mutex.h - scudo - Git at Google

 //===-- mutex.h -------------------------------------------------*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #ifndef SCUDO_MUTEX_H_
 #define SCUDO_MUTEX_H_

 #include "atomic_helpers.h"
 #include "common.h"
 #include "thread_annotations.h"

 #include <string.h>

 #if SCUDO_FUCHSIA
 #include <lib/sync/mutex.h> // for sync_mutex_t
 #endif

 namespace scudo {

 class CAPABILITY("mutex") HybridMutex {
 public:
   bool tryLock() TRY_ACQUIRE(true);
   NOINLINE void lock() ACQUIRE() {
     if (LIKELY(tryLock()))
       return;
       // The compiler may try to fully unroll the loop, ending up in a
       // NumberOfTries*NumberOfYields block of pauses mixed with tryLocks. This
       // is large, ugly and unneeded, a compact loop is better for our purpose
       // here. Use a pragma to tell the compiler not to unroll the loop.
 #ifdef __clang__
 #pragma nounroll
 #endif
     for (u8 I = 0U; I < NumberOfTries; I++) {
       delayLoop();
       if (tryLock())
         return;
     }
     lockSlow();
   }
   void unlock() RELEASE();

   // TODO(chiahungduan): In general, we may want to assert the owner of lock as
   // well. Given the current uses of HybridMutex, it's acceptable without
   // asserting the owner. Re-evaluate this when we have certain scenarios which
   // requires a more fine-grained lock granularity.
   ALWAYS_INLINE void assertHeld() ASSERT_CAPABILITY(this) {
     if (SCUDO_DEBUG)
       assertHeldImpl();
   }

 private:
   void delayLoop() {
     // The value comes from the average time spent in accessing caches (which
     // are the fastest operations) so that we are unlikely to wait too long for
     // fast operations.
     constexpr u32 SpinTimes = 16;
     volatile u32 V = 0;
     for (u32 I = 0; I < SpinTimes; ++I) {
       u32 Tmp = V + 1;
       V = Tmp;
     }
   }

   void assertHeldImpl();

   // TODO(chiahungduan): Adapt this value based on scenarios. E.g., primary and
   // secondary allocator have different allocation times.
   static constexpr u8 NumberOfTries = 32U;

 #if SCUDO_LINUX
   atomic_u32 M = {};
 #elif SCUDO_FUCHSIA
   sync_mutex_t M = {};
 #endif

   void lockSlow() ACQUIRE();
 };

 class SCOPED_CAPABILITY ScopedLock {
 public:
   explicit ScopedLock(HybridMutex &M) ACQUIRE(M) : Mutex(M) { Mutex.lock(); }
   ~ScopedLock() RELEASE() { Mutex.unlock(); }

 private:
   HybridMutex &Mutex;

   ScopedLock(const ScopedLock &) = delete;
   void operator=(const ScopedLock &) = delete;
 };

 } // namespace scudo

 #endif // SCUDO_MUTEX_H_
	//===-- mutex.h -------------------------------------------------- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#ifndef SCUDO_MUTEX_H_
	#define SCUDO_MUTEX_H_

	#include "atomic_helpers.h"
	#include "common.h"
	#include "thread_annotations.h"

	#include <string.h>

	#if SCUDO_FUCHSIA
	#include <lib/sync/mutex.h> // for sync_mutex_t
	#endif

	namespace scudo {

	class CAPABILITY("mutex") HybridMutex {
	public:
	bool tryLock() TRY_ACQUIRE(true);
	NOINLINE void lock() ACQUIRE() {
	if (LIKELY(tryLock()))
	return;
	// The compiler may try to fully unroll the loop, ending up in a
	// NumberOfTries*NumberOfYields block of pauses mixed with tryLocks. This
	// is large, ugly and unneeded, a compact loop is better for our purpose
	// here. Use a pragma to tell the compiler not to unroll the loop.
	#ifdef __clang__
	#pragma nounroll
	#endif
	for (u8 I = 0U; I < NumberOfTries; I++) {
	delayLoop();
	if (tryLock())
	return;
	}
	lockSlow();
	}
	void unlock() RELEASE();

	// TODO(chiahungduan): In general, we may want to assert the owner of lock as
	// well. Given the current uses of HybridMutex, it's acceptable without
	// asserting the owner. Re-evaluate this when we have certain scenarios which
	// requires a more fine-grained lock granularity.
	ALWAYS_INLINE void assertHeld() ASSERT_CAPABILITY(this) {
	if (SCUDO_DEBUG)
	assertHeldImpl();
	}

	private:
	void delayLoop() {
	// The value comes from the average time spent in accessing caches (which
	// are the fastest operations) so that we are unlikely to wait too long for
	// fast operations.
	constexpr u32 SpinTimes = 16;
	volatile u32 V = 0;
	for (u32 I = 0; I < SpinTimes; ++I) {
	u32 Tmp = V + 1;
	V = Tmp;
	}
	}

	void assertHeldImpl();

	// TODO(chiahungduan): Adapt this value based on scenarios. E.g., primary and
	// secondary allocator have different allocation times.
	static constexpr u8 NumberOfTries = 32U;

	#if SCUDO_LINUX
	atomic_u32 M = {};
	#elif SCUDO_FUCHSIA
	sync_mutex_t M = {};
	#endif

	void lockSlow() ACQUIRE();
	};

	class SCOPED_CAPABILITY ScopedLock {
	public:
	explicit ScopedLock(HybridMutex &M) ACQUIRE(M) : Mutex(M) { Mutex.lock(); }
	~ScopedLock() RELEASE() { Mutex.unlock(); }

	private:
	HybridMutex &Mutex;

	ScopedLock(const ScopedLock &) = delete;
	void operator=(const ScopedLock &) = delete;
	};

	} // namespace scudo

	#endif // SCUDO_MUTEX_H_